Temperature limits of mitosis in mammalian cell cultures]

Mammalian cells of different origin (11 strains) were cultivated at the temperature of 25--41 degrees to measure the temperature limits of mitosis. Different strains of the cells reacted to the increase or decrease in the cultivation temperature in a dissimilar way. The difference between the upper temperature limit and the optimum one was not over 5 degrees. Cell division did not end with the temperature fall by over 10 degrees. Various cell strains responded to the temperature decrease in a different way. Most cellular population had three cell types. The majority of the cells were capable of dividing at the threshold temperature; some cells could enter mitosis without completing it and stop at the metaphase. The temperature limits of mitosis were not related to the species and tissue origin of the cells.     

Global chromosome positions are transmitted through mitosis in mammalian cells

We investigated positioning of chromosomes during the cell cycle in live mammalian cells with a combined experimental and computational approach. By non-invasive labeling of chromosome subsets and tracking by 4D imaging, we could show that no global rearrangements occurred in interphase. Using the same assay, we also observed a striking order of chromosomes throughout mitosis. By contrast, our computer simulation based on stochastic movements of individual chromosomes predicted randomization of chromosome order in mitosis. In vivo, a quantitative assay for single chromosome positioning during mitosis revealed strong similarities between daughter and mother cells. These results demonstrate that global chromosome positions are heritable through the cell cycle in mammalian cells. Based on tracking of labeled chromosomes and centromeres during chromosome segregation and experimental perturbations of chromosomal order, we propose that chromosome specific timing of sister chromatid separation transmits chromosomal positions from one cell generation to the next.     

Regulating apoptosis in mammalian cell cultures

Cell culture technology has become a widely accepted method used to derive therapeutic and diagnostic protein products. Mammalian cells adapted to grow in bioreactors now play an integral role in the development of these biologicals. A major limiting factor determining the output efficiency of mammalian cell cultures however, is apoptosis or programmed cell death. Methods to delay apoptosis and increase the longevity of cell cultures can lead to more economical processes. Researchers have shown that both genetic and chemical strategies to block apoptotic signals can increase cell culture productivity. Here, we discuss various strategies which have been implemented to improve cellular viabilities and productivities in batch cultures.     

Defining viability in mammalian cell cultures

A large number of assays are available to monitor viability in mammalian cell cultures with most defining loss of viability as a loss of plasma membrane integrity, a characteristic of necrotic cell death. However, the majority of cultured cells die by apoptosis and early apoptotic cells, although non-viable, maintain an intact plasma membrane and are thus ignored. Here we measure the viability of cultures of a number of common mammalian cell lines by assays that measure membrane integrity (a measure of necrotic cell death) and assays that measure apoptotic cells, and show that discrepancies in the measurement of culture viability have a significant impact on the calculation of cell culture parameters and lead to skewed experimental data.     

Kinetochores and microtubules in multipolar mitosis and chromosome orientation.

The ultrastructure of the kinetochore and the orientation of kinetochore microtubules were studied in multipolar divisions of cultured rat-kangaroo cells (Pt-K1). The metaphase kinetochore exhibited a lamellar structure and most of the chromosomes expressed a bipolar microtubule orientation. A multipolar kinetochore orientation was observed in some chromosomes. Equal or unequal portions of a chromatid's kinetochore and a corresponding number of kinetochore microtubules may be oriented to two different poles. Curved or bent continuous microtubules were observed in the vicinity of chromosomes showing multipolar orientation. The findings are in accordance with Östergren's theory of ‘auto-orientation’ [8]. It is speculated that orientation of a chromatid kinetochore to more than one pole might be a possible regular event during the process of chromosome orientation prior to full metaphase in bipolar mitosis.     

Detection of sequestered calcium during mitosis in mammalian cell cultures and in mitotic apparatus isolated from sea urchin zygotes

Chlorotetracycline, which fluoresces in the presence of divalent cations in membrane environments, has been employed to localize sequestered calcium in dividing cells and isolated mitotic apparatus. HeLa and CHO cells during division have cytoplasmic granules that fluoresce in the presence of Chlorotetracycline with spectral characteristics similar to those of calcium chelates. Mitotic apparatus isolated from dividing sea urchin zygotes fluoresce with punctate sources in the presence of Chlorotetracycline. The intensity of fluorescence is markedly reduced by membrane disruption with detergents and is unaffected by exogenous calcium chelators. It is concluded that membranes found in association with the mitotic apparatus, revealed by electron microscopy, can sequester cytoplasmic calcium ions. It is proposed that this sequestration, which would result in altered cytoplasmic calcium concentrations, may participate in the regulation of microtubule stability during division.     

Pattern of DNA segregation in multipolar anatelophases of different ploidy in euploid and aneuploid mammalian cells cultivated in vitro

A microdensitometrical analysis of multipolar anatolophases of cuploid and aneuploid mammalian cells in vitro has been made in order to study the quantitative distribution of DNA to the poles.In the tripolar anatelophases of aneuploid Chinese hamster cells (obtained using colchicine) DNA is distributed to poles in an almost random way. In the spontaneous tripolar anatelophases of euploid cells of Rhesus, DNA is distributed to the poles in whole number multiples of 1c. The following distributions were observed in tetraploid cells: 14 cases of 3 : 3 : 2 and 3 cases of 4 : 2 : 2. In triploid cells, 6 cases of 2 : 2 : 2 and 1 case of 3 : 2 : 1.Thus we have deduced that each ploidy degree has a preferential distribution of sets and in contrast to the original hypothesis, random segregation of the sets is not the common occurrence. Hypotheses have been made to explain the origin of multipolar mitosis and the preferential distribution of chromatid sets to the poles. The results would confirm the existence of haploid sets of chromatids and would explain the appearance of triploid, pentaploid and hexaploid cells in tissues and cell cultures.     

Metabolic flux rewiring in mammalian cell cultures

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Asbestos-Mediated transfection of mammalian cell cultures

Summary The capacity of asbestos to mediate transfection was tested in a rapid and relatively simple system: picornavirus RNAs and mammalian cells in vitro. Thirteen asbestos samples, including amosite, anthophyllite, chrysotile, and crocidolite, 4 picornaviruses (poliovirus 1 and 2, echovirus 7, and encephalomyocarditis virus), and 4 cell lines (CLI, chimpanzee liver; KB, human carcinoma eta, monkey kidney; NIH 3T3, mouse embryo) were tested. The results showed that all asbestos samples mediated transfection and that all cell lines were transfectible by viral RNA with asbestos. Transfection was much greater with asbestos added to the viral RNA inoculum than to the cells before or after the RNA. Transfection was directly proportional to asbestos concentration. Initiation of transfection events was rapid, with half becoming irreversible by washing 2 min postinoculation. DNA in the inoculum strongly interfered with asbestos-mediated transfection by the RNA but was ineffective when added, with or without asbestos, to the cells before or after the inoculum. Asbestos compared with six classical “insoluble” facilitators (bentonite, calcium phosphate, chromic oxide, ferric oxide, kaolin, talc) was of intermediate rank in transfection mediation. It is hypothesized that the prominence of asbestos in carcinogenesis is due to a combination of properties, including transfection mediation as well as chromosome mutagenicity, fiber dimensions, biological durability, hydrocarbon transport, and prevalence.     

Studies of multipolar mitoses in euploid tissue cultures

Cultures of kidney epithelium and fibroblasts of 39 specimens of Microtus agrestis were investigated. In all 77 cultures multipolar mitoses were found. They were studied in living state and after pulse labelling with ³H-thymidine. The ploidy of the multipolar mitoses and of their daughter nuclei was determined by measuring the relative Feulgen-DNA content and by counting the predominantly constitutive heterochromatic sex chromosomes. Constitutive heterochromatin was demonstrated by late replication, retarded separation of the chromatids in anaphase, heteropycnosis and by the Giemsa technique of Arrighi and Hsu (1971). The latter stained also the spindle apparatus of mitoses.—In living cells, transformation of multipolar mitoses into bipolar mitoses was observed. The chromosomes of multipolar mitoses are separated into complete genomes; the daughter nuclei can be haploid, diploid, triploid or tetraploid. The chromosomes of haploid and triploid metaphases were studied with the Giemsa banding technique. The banding pattern shows an exact monosomy and trisomy, respectively, for each chromosome. Haploid nuclei are likely to be viable only in multinucleate cells, whereas triploid cells behave like diploid cells during the S period and the mitosis.Dedicated to Prof. Dr. K. Goerttler on the occasion of his 75th birthday.Supported by the Bundesministerium für Bildung und Wissenschaft of the Federal Republic of Germany.     

Studies of multipolar mitoses in euploid tissue cultures

In tissue cultures of male Microtus agrestis, diploid mitoses with two X or two Y chromosomes were found. For identifiying the sex chromosomes in nonhypotonioally treated mitoses, the asynchrony of DNA replication of the sex chromosomes of both sexes was used. The constitutive heterochromatin of Y replicates later in the S period than X, and X₂ of the female replicates later than X₁. Autoradiographic studies of tetraploid tripolar mitoses showed that the diploid daughter nuclei contain either XX or YY in the male; in the female, X₁X₂ daughter nuclei were found less frequently than X₁X₁ and X₂X₂ cells.     

Cell cycle kinetics of insect cell cultures compared to mammalian cell cultures

Cell cycle kinetics of lepidopteran cell lines Sf9 (Spodoptera frugiperda) and IZDMb0503 (Mamestra brassicae) were investigated and compared to mammalian cell cycle distributions. The resting phase (G₀) of mammalian cells is characterized by a 2c-DNA content whereas G₀-phase of insect cell lines is characterized by a 4c-DNA content. Flow cytometric data in combination with growth curves of partially synchronized and asynchronously growing cells proved the existence of this phenomenon. Kinetics of cells labeled by the thymidine analog on 5-bromo-2′-deoxyuridine supported these results, which now render the possibility of applying cell cycle analysis in fermentation technology of insect cells.     

p53 dependent centrosome clustering prevents multipolar mitosis in tetraploid cells

Backgroundp53 abnormality and aneuploidy often coexist in human tumors, and tetraploidy is considered as an intermediate between normal diploidy and aneuploidy. The purpose of this study was to investigate whether and how p53 influences the transformation from tetraploidy to aneuploidy.Conclusionsp53 could not prevent tetraploid cells entering mitosis or induce tetraploid cell death. However, p53 abnormality impaired centrosome clustering and lead to multipolar mitosis in tetraploid cells by modulating the RhoA/ROCK signaling pathway.     

Further studies on a mutant mammalian cell line defective in mitosis

Experiments have been performed on a temperature-sensitive hamster cell line, ts-546. After the cells are switched to the non-permissive temperature, interphase cells continue through the cell cycle until the cells enter metaphase. Normal mitotic events then fail to occur. Metaphase chromosomes in the cells condense and coalesce into chromatin aggregates. Nuclear membrane re-forms around the aggregates resulting in the formation of mono-, bi- or multi-nucleate interphase-like cells. The conversion of mitotic cells to interphase-like states is completed within a few hours. The initial characterization of the mutant cell line was based on the observation that rounded-up cells accumulate in culture at the non-permissive temperature. The mitotic roundingup process may be utilized as a useful marker for selective isolation of mutant cell lines defective in mitosis.